Abstract
First direct evidence for ongoing gas seepage activity on the abandoned well site 22/4b (Northern North Sea, 57°55′ N, 01°38′ E) and discovery of neighboring seepage activity is provided from observations since 2005. A manned submersible dive in 2006 discovered several extraordinary intense seepage sites within a 60 m wide and 20 m deep crater cut into the flat 96 m deep seafloor. Capture and (isotope) chemical analyses of the gas bubbles near the seafloor revealed in situ concentrations of methane between 88 and 90%Vol. with δ13C–CH4 values around −74‰ VPDB, indicating a biogenic origin. Bulk methane concentrations throughout the water column were assessed by 120 Niskin water samples showing up to 400.000 nM CH4 in the crater at depth. In contrast, concentrations above the thermocline were orders of magnitude lower, with a median value of 20 nM. A dye tracer injection into the gas seeps revealed upwelling bubble and water motion with gas plume rise velocities up to ∼1 ms−1 (determined near the seabed). However, the dissolved dye did not pass the thermocline, but returned down to the seabed. Measurements of direct bubble-mediated atmospheric flux revealed low values of 0.7 ± 0.3 kty−1, much less than current state-of-the-art bubble dissolution models would predict for such a strong and upwelling in situ gas bubble flux at shallow water depths (i.e. ∼100 m).Acoustic multibeam water column imaging data indicate a pronounced 200 m lateral intrusion at the thermocline together with high methane concentration at this layer. A partly downward-orientated bubble plume motion is also visible in the acoustic data with potential short-circuiting in accordance to the dye experiment. This observation could partly explain the observed trapping of most of the released gas below the well-established thermocline in the North Sea. Moreover, 3D analyses of the multibeam water column data reveal that the upwelling plume transforms into a spiral expanding vortex while rising through the water column. Such a spiral vortex motion has never been reported before for marine gas seepage and might represent an important process with strong implication on plume dynamics, dissolution behavior, gas escape to the atmosphere, and is considered very important for respective modeling approaches.
Highlights
IntroductionNatural and man-made subsea methane release in the North Sea. Natural methane release from the seafloor by seep processes is observed virtually on all continental margins (Judd and Hovland, 2007)
Concentrations slightly above 15 nM were encountered in an area close to the blowout site between 57°48 N and 58°18 N, 1°6 –1°45 E
Vigorous gas bubble discharge with upwelling was observed in the blowout crater transporting large quantities of methane bubbles into the water column
Summary
Natural and man-made subsea methane release in the North Sea. Natural methane release from the seafloor by seep processes is observed virtually on all continental margins (Judd and Hovland, 2007). Estimates suggest marine seeps may contribute ∼10– 30 Tg yr−1 (Kvenvolden et al, 2001) to global geological methane emissions of 30–45 Tg yr−1 (Etiope and Klusman, 2002). The significance of marine methane seepage for the total atmospheric methane budget and global warming is still under debate (Ciais et al, 2013). J. Schneider von Deimling et al / Marine and Petroleum Geology 68 (2015) 718–730
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